Perturbation Methods in the Quantum Mech
✍ E. M. Corson
📂 Library
📅 1951
🏛 Hafner
🌐 English
✦ LIBER ✦
📁
The Matrix Perturbation Method in Quantum Mechanics
✍ Scribed by Francisco Soto-Eguibar, Braulio Misael Villegas-Martínez, Héctor Manuel Moya-Cessa
- Publisher
- Springer
- Year
- 2024
- Tongue
- English
- Leaves
- 201
- Category
- Library
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✦ Synopsis
This book provides an alternative approach to time-independent perturbation theory in non-relativistic quantum mechanics. It allows easy application to any initial condition because it is based on an approximation to the evolution operator and may also be used on unitary evolution operators for the unperturbed Hamiltonian in the case where the eigenvalues cannot be found. This flexibility sets it apart from conventional perturbation theory. The matrix perturbation method also gives new theoretical insights; for example, it provides corrections to the energy and wave function in one operation. Another notable highlight is the facility to readily derive a general expression for the normalization constant at m-th order, a significant difference between the approach within and those already in the literature. Another unique aspect of the matrix perturbation method is that it can be extended directly to the Lindblad master equation. The first and second-order corrections are obtained for this equation and the method is generalized for higher orders. An alternative form of the Dyson series, in matrix form instead of integral form, is also obtained. Throughout the book, several benchmark examples and practical applications underscore the potential, accuracy and good performance of this novel approach. Moreover, the method's applicability extends to some specific time-dependent Hamiltonians. This book represents a valuable addition to the literature on perturbation theory in quantum mechanics and is accessible to students and researchers alike.
✦ Table of Contents
Preface
Introduction: Matrix Perturbation Method—A New Approach to Time-Independent Quantum Perturbation Theory
References
Contents
1 Standard Time-Independent Perturbation Theory
1.1 Introduction
1.2 Discrete Non-degenerated Spectrum
1.2.1 Example: The One Dimensional Harmonic Oscillator with a Cubic Perturbation
1.3 Discrete Degenerated Spectrum
1.3.1 Example: The Three-Dimensional Isotropic Harmonic Oscillator with an xy Perturbation
1.3.2 Example: The Stark Effect in the Hydrogen Atom
References
2 Standard Time-Dependent Perturbation Theory
2.1 Introduction
2.2 Method of Variation of Constants
2.2.1 Time-Dependent Perturbation Theory When the Spectrum Is Discrete
2.2.1.1 Finite Time Perturbation
2.2.1.2 Constant Perturbation
2.2.2 Time-Dependent Perturbation Theory When the Spectrum Is Discrete and Continuous
2.2.2.1 Monochromatic Perturbation
2.3 Method of Dyson Series
2.3.1 Constant Perturbation
2.4 Transition Probabilities
2.4.1 Constant Perturbation
References
3 The Matrix Perturbation Method
3.1 Introduction
3.2 Matrix Approach to the Perturbation Theory
3.2.1 First-Order Correction
3.2.2 Second-Order Correction
3.2.3 Higher Order Corrections
3.3 Normalization Constant
3.4 Connection with the Standard Time-Independent Perturbation Theory
3.5 The Dyson Series in the Matrix Method
References
4 Examples of the Matrix Perturbation Method
4.1 Introduction
4.2 The Harmonic Oscillator Perturbed by a Linear Anharmonic Term
4.2.1 The Exact Solution
4.2.1.1 A Coherent State as Initial State
4.2.2 The Approximated Perturbative Solution
4.2.2.1 Zero-Order Term
4.2.2.2 First-Order Term
4.2.2.3 Second-Order Term
4.2.2.4 The Perturbative Solution Up to Second Order
4.2.3 Comparison Between the Exact and the Approximated Solutions
4.2.3.1 The Exact and the Approximated Solutions for ω=1, λ=0.01, and α=4 at Different Times
4.2.3.2 The Exact and the Approximated Solutions for ω=1, λ=0.01, and α=10 at Different Times
4.2.3.3 The Exact and the Approximated Solutions for ω=1, λ=0.1, and α=10 at Different Times
4.2.3.4 Does the Coincidence Regime Depend on the Initial Condition?
4.3 The Harmonic Oscillator Plus a Cubic Potential
4.3.1 First Order
4.3.1.1 A Number State m as Initial State
4.3.1.2 A Coherent State α as Initial State
4.3.2 Second Order
4.3.3 Initial Condition Equal to a Number State
4.4 The Repulsive Quadratic Potential Plus a Linear Term
4.4.1 Exact Solution of the Repulsive Quadratic Potential
4.4.2 Exact Solution to the Quadratic Repulsive Potential Plus a Linear Term
4.4.3 Perturbative Solution
4.4.3.1 Zero-Order Correction
4.4.3.2 First-Order Correction
4.4.3.3 Second-Order Correction
4.4.3.4 The Solution to Second Order
4.4.3.5 A Coherent State as Initial State
4.4.3.6 The Normalized Solution
4.4.3.7 A Cat State as Initial State
4.4.4 Comparison of the Exact and the Perturbative Solutions
References
5 Applications of the Matrix Perturbation Method
5.1 Introduction
5.2 Trapped Ion Hamiltonian
5.2.1 High Intensity Regime
5.2.1.1 First-Order Correction
5.2.1.2 Second-Order Correction
5.2.1.3 Comparison of the Perturbative Solution with the Small Rotation Approximation Solution
5.3 Perturbative Solution for the Rabi Model
5.4 The Binary Waveguide Array
5.4.1 Exact Solution
5.4.2 Small Rotation Approximated Solution
5.4.3 Matrix Perturbative Solution
5.4.3.1 Zero-Order Perturbative Solution
5.4.3.2 First-Order Perturbative Solution
5.4.3.3 Second-Order Perturbative Solution
5.4.3.4 Third-Order Perturbative Solution
5.4.4 Comparison of the Perturbative Solution with the Exact Solution and with the Small Rotation Solution
References
6 The Matrix Perturbation Method for the Lindblad Master Equation
6.1 Introduction
6.2 Lindblad Master Equation
6.2.1 First-Order Correction
6.2.2 Second-Order Correction
6.2.3 Higher Orders
6.3 Lossy Cavity Filled with a Kerr Medium
6.3.1 Exact Solution
6.3.2 Perturbative Solution
6.3.2.1 First-Order Correction
6.3.2.2 Second-Order Correction
6.4 Comparison Between the Exact and the Approximated Solution
References
7 Eliminating the Time Dependence for a Class of Time-Dependent Hamiltonians
7.1 Introduction
7.2 First Case
7.2.1 A Particle with Strongly Pulsating Mass Moving in a Linear Potential
7.2.1.1 Exact Solution
7.2.1.2 Perturbative Solution
7.2.1.3 Comparison Between the Exact and Perturbative Solutions
7.2.2 A Particle with Exponentially Increasing Mass in the Presence of a Linear Potential
7.2.2.1 Exact Solution
7.2.2.2 Perturbative Solution
7.2.2.3 Comparison Between the Exact and Perturbative Solutions
7.3 Second Case
7.3.1 Example
7.3.1.1 Exact Solution
7.3.1.2 Perturbative Solution
7.3.1.3 Comparison Between the Exact and Perturbative Solutions
7.3.2 Other Examples
7.3.2.1 Harmonic Oscillator with a Quadratically Growing Mass
7.3.2.2 Forced Caldirola–Kanai Oscillator
7.3.2.3 Particle with a Hyperbolic Growing Mass
References
Index
📜 SIMILAR VOLUMES
Large Order Perturbation Theory and Summ
✍ G. A. Arteca, F. M. Fernández, E. A. Castro (auth.)
📂 Library
📅 1990
🏛 Springer-Verlag Berlin Heidelberg
🌐 English
<p>The book provides a general, broad approach to aspects of perturbation theory. The aim has been to cover all topics of interest, from construction, analysis, and summation of perturbation series to applications. Emphasis is placed on simple methods, as well as clear, intuitive ideas stemming from
M(atrix) theory: matrix quantum mechanic
✍ Taylor W.
📂 Library
📅 2001
🌐 English
This article reviews the matrix model of M theory. M theory is an 11-dimensional quantum theory of gravity that is believed to underlie all superstring theories. M theory is currently the most plausible candidate for a theory of fundamental physics which reconciles gravity and quantum field theory i
Quantum Mechanics in Matrix Form
✍ Günter Ludyk (auth.)
📂 Library
📅 2018
🏛 Springer International Publishing
🌐 English
<p><p>This book gives an introduction to quantum mechanics with the matrix method. Heisenberg's matrix mechanics is described in detail. The fundamental equations are derived by algebraic methods using matrix calculus. Only a brief description of Schrödinger's wave mechanics is given (in most books
Quantum Mechanics in Matrix Form
✍ Günter Ludyk
📂 Library
📅 2018
🏛 Springer
🌐 English
<p>This book gives an introduction to quantum mechanics with the matrix method. Heisenberg's matrix mechanics is described in detail. The fundamental equations are derived by algebraic methods using matrix calculus. Only a brief description of Schrödinger's wave mechanics is given (in most books exc
Perturbation Methods in Fluid Mechanics
✍ Milton D. Van Dyke, Milton Van Dyke
📂 Library
📅 1975
🏛 Parabolic Pr
🌐 English
Techniques for treating regular and singular perturbations are illustrated by application to problems of fluid motion. In particular, the method of matched asymptotic expansions is applied to the aerodynamics of airfoils and wings, and to viscous flow at high and low Reynolds numbers. Other topics i